KR0128665Y1 - Output circuit of smps - Google Patents

Abstract

The present invention relates to a power supply, and more particularly, to an output circuit of a power supply that can reduce the power consumption by controlling the output power of the power supply. The power control unit 30 according to the present invention has a transistor Q31 for switching according to the mode switching signal CL and an output voltage Vo1 of the first power output unit 20 according to the switching state of the transistor Q31. Resistor R31 for biasing the transistor Q31 to the transistor Q31, the transistor Q32 for switching off by the output signal of the transistor Q31, and the resistor R32 through which current flows according to the switching state of the transistor Q32. ) And the zener diode ZD31, the transistor Q33 for switching according to the switching state of the transistor Q32, and the output voltage Vo1 of the first power output unit 20A by switching according to the switching state of the transistor Q33. ) Is provided as a transistor Q34 for applying to the regulator REG.

Description

Output circuit of power supply

1 is a view showing the configuration of a general power supply.

2 is a view showing the configuration of the output circuit of the power supply according to the present invention.

* Explanation of symbols for main parts of the drawings

10: power input unit 20A, 20B: first and second power output unit

30: power control unit 40: power detection unit

50: control unit R31, R32: resistance

Q31 to Q34: transistor ZD31: zener diode

The present invention relates to a power supply, and more particularly, to an output circuit of a power supply that can reduce the power consumption of the power control unit by distributing transistors of the output power of the power supply.

As shown in FIG. 1, a general power supply device includes a power input unit 1 for full-wave rectifying and smoothing an input AC power and applying it to a transformer T, and a first coil of a secondary side of the transformer T. The first and second power supply outputs 2A and 2B, which are applied to the load LD1 and the regulator REG by smoothing the excitation voltage of (L1) and (L2) after half-wave rectification, and the micro-not shown in the figure. A power supply control section 3 for controlling the output voltage Vo1 of the first power supply output section 2A according to the output signal of the processor, and a power detection section 4 for remotely detecting and transmitting the amount of current flowing through the power supply control section 3; ), And a control section 5 for switching the control signal generated according to the output signal of the power supply detecting section 4 to control the driving of the transformer T.

The power input unit 1 includes a bridge diode BD for full-wave rectifying the input AC power AC, a resistor Rin for removing an inrush current of an output signal of the bridge diode BD, and a resistor Rin. It consists of a capacitor (Cin) for smoothing the output signal.

In addition, the first power output unit 2A rectifies and smoothes the organic current of the first coil L1 of the secondary side of the transformer T and smoothes the diode Do1 and the capacitor Co1 to be applied to the load LD1. The second power output unit 2B rectifies and smoothes the organic current of the secondary-side second coil L2 of the transformer T, and smoothes and applies the diode Do2 and the capacitor Co2 to the regulator RG. It consists of.

The power supply control unit 3 switches the transistor Q31 for switching by the mode switching signal CL input according to the mode, and the output voltage of the first power output unit 2A according to the switching state of the transistor Q31. Resistor R31 and Zener diode ZD31 for controlling Vo1 and the output signal of the resistor R31 and Zener diode ZD31 are applied and switched according to the switching state of the transistor Q31. And a resistor R32 for protecting the transistor Q32 and a switching state of the transistor Q32 to apply the output voltage Vo1 of the first power output unit 2A to the regulator RG. The transistor Q33 is configured.

The power detector 4 is configured of a photodiode that detects the output current of the power controller 3 and remotely transmits it as an output signal.

In addition, the controller 5 receives the output signal of the power detector 4 to control the current flowing through the primary coil of the transformer T, thereby outputting the output voltages of the first and second power output units 2A and 2B. It is configured to keep (Vo1) (Vo2) constant.

In the above power supply device, the AC power input is full-wave rectified by the bridge diode BD of the power input unit 1, and the current rectified signal is inrushed by the resistor Rin. The current is removed.

The output signal of the resistor (Rin) is smoothed by the capacitor (Cin) and then applied to the primary coil of the transformer (T).

At this time, the current flowing in the primary side first coil L1 of the transformer T is induced to the secondary side first coil L1 of the transformer T according to the control signal output from the controller 5, and the induced current. Is half-wave rectified by the diode Do1 of the first power output unit 2A. The output signal of the diode Do1 is smoothed by the capacitor Co1.

In addition, the induced current of the secondary coil L2 of the transformer T is half-wave rectified by the diode Do2 of the power output unit 2B, and the output signal of the diode Do2 is the capacitor Co2. After smoothing by), it is applied to the regulator (REG) and converted to a constant voltage.

On the other hand, when the mode of the monitor is the normal mode, the mode switching signal CL outputted in the high potential state is applied to the transistor Q31 of the power supply control unit 3 to switch the transistor Q31 to the on state, The output voltage Vo1 of the first power output unit 2A is applied to the ground of the transistor Q31 through the resistor R31 and the zener diode ZD31 by the turn-on state of the transistor Q31.

Therefore, the transistor Q32 is switched to the turn-off state by the turn-on state of the transistor Q31, and the transistor Q33 is switched to the turn-off state by the turn-off state of the transistor Q32. .

That is, the output voltage Vo1 of the first power output unit 2A is applied to the load LD1 to drive the load LD1, and at the same time, the output voltage Vo2 of the second power output unit 2B is The voltage is converted to a constant voltage through the regulator REG and then applied to the load LD2 to drive the load LD2.

At this time, the current flowing through the resistor R31 and the zener diode ZD31 of the power control unit 3 is sensed by the photodiode of the power detection unit 4, and the current flowing through the photodiode is transmitted remotely as an output signal. .

The output signal of the remotely transmitted power supply control unit 3 is applied to the control unit 5 so that the duty of the control signal is varied according to the output signal, and 2 in the primary coil of the transformer T is triggered by the trigger of the control signal. The amount of current induced by the vehicle side first coil L1 and the second coil L2 is controlled.

When the amount of current flowing through the resistor R31 of the power control unit 3 and the zener diode ZD31 in order to supply high voltage to the load LD1 in the power supply device as described above is reduced, the photodiode of the power detector 4 The amount of current flowing in the filter is increased, and the switching time of the controller 5 becomes long according to the output signal of the power detector 4 that is increased by the increased amount of current, so that the first coil of the secondary side of the primary coil of the transformer T is increased. The amount of current induced by the coil L1 and the second coil L2 increases.

However, as described above, in order to reduce the amount of current flowing through the resistor R31 and the negative diode ZD31 in the normal mode of the general power supply, the value of the resistor R31 must be large, and the value of the resistor R31 is large. When the voltage drop of the resistor R31 is increased, heat is generated, and the heat has a problem of shortening the life of the power supply.

The present invention uses a transistor that distributes the output voltage of the first power output unit and the second power output unit to the base side and the collector side in order to solve such a problem, thereby reducing the power consumption of the power control unit to reduce heat generation It is an object of the present invention to provide an output circuit of a power supply which can extend the life of the power supply and improve the reliability of the power supply.

The present invention for realizing the above object is a power control unit for applying the output voltage of the first and second power output unit to the load and the regulator according to the mode switching signal, and a power supply for remotely transmitting the current amount flowing through the power control unit as an output signal. A power supply comprising a detector and a controller for controlling a current flowing in a primary side of a transformer by varying a switching frequency in accordance with an output signal of the power detector, the transistor being switched by the power controller in accordance with a mode switching signal; A resistor for biasing the output voltage of the first power output section to the transistor in accordance with the switching state of the transistor, a transistor for switching to a turn-off state by the output signal of the transistor, a resistor and zener through which current flows according to the switching state of the transistor Depending on the diode and the switching state of this transistor, The switching transistor in accordance with the call and the switching state of the transistor having been made in a transistor that applies a first output voltage output of the power regulator.

Hereinafter, described in detail by the accompanying drawings as follows.

2 is a view showing the configuration of a power supply device according to the present invention, as shown in the power input unit 10, the first and second power output unit 20A (20B), power detection unit 40 And the controller 50 is configured in the same manner as in FIG. 1, and the power controller 30 is configured to perform a switching operation according to the mode switching signal CL and a first power supply according to the switching operation of the transistor Q31. A resistor R31 for biasing the output voltage Vo1 of the output portion 20A to the transistor Q31, a transistor Q32 which switches to a turn-off state as the transistor Q31 is turned on, and this transistor; The resistor R32 and zener diode ZD31 through which a current flows according to the switching state of Q32, the transistor Q33 switching according to the switching state of the transistor Q32, and the switching state of this transistor Q33 Switch according to the output voltage V of the first power output unit 20A. transistor Q34 for applying o1) to regulator REG.

On the other hand, the operation of the present invention made in such a configuration in detail as follows.

First, the input AC power Ac is full-wave rectified by the bridge diode BD of the power input unit 10, and the inrush current of the signal is removed by the resistor Rin.

The output signal of the resistor (Rin) is smoothed by the capacitor (Cin) and then applied to the primary coil of the transformer (T).

At this time, according to the control signal output from the controller 50, the secondary coil of the transformer T flowing in the primary coil of the transformer T is induced to the first coil (L1), the induced current is the first power output unit ( Half-wave rectified by the diode Do1 of 20A). The output signal of the diode Do1 is smoothed by the capacitor Co1.

In addition, the induced current of the secondary coil L2 of the transformer T is half-wave rectified by the diode Do2 of the second power output unit 20B, and the output signal of the diode Do2 is a capacitor. After smoothing by Co2, it is applied to the regulator REG and converted to a constant voltage.

Here, when the mode of the monitor is the normal mode, the mode switching signal CL outputted in the high potential state is applied to the transistor Q31 of the power supply control unit 30 to switch the transistor Q31 to the on state. Due to the turned-on state of the transistor Q31, the output voltage Vo1 of the first power output unit 20 is biased to the transistor Q31 through the resistor R31.

In addition, since the transistor Q32 is turned off by the turn-on state of the transistor Q31, almost no current flows in the resistor R31 and the zener diode ZD31.

Therefore, the transistor Q33 is switched to the turn-off state by the turn-off state of the transistor Q32, and the transistor Q34 is switched to the turn-off state by the turn-off state of the transistor Q33. .

That is, the output voltage Vo1 of the first power output unit 20A is applied to the load LD1 to drive the load LD1, and at the same time, the output voltage Vo2 of the second power output unit 20B is The voltage is converted to a predetermined voltage through the regulator REG and applied to the load LD2 to drive the load LD2.

At this time, since the amount of current flowing through the resistor R32 and the zener diode ZD31 of the power supply control unit 30 is small, the amount of current flowing through the photodiode of the power supply detection unit 40 becomes large, and the amount of current flowing through the increased photodiode is output signal Remote transmission.

The output signal of the power control unit 30 is applied to the control unit 50 so that the switching frequency of the control signal increases according to the output signal so that the current flowing through the primary coil of the transformer T becomes the secondary coil of the transformer T. Since much is induced, high voltage is output from the first and second power output units 20A and 20B.

In addition, when the mode of the monitor is in the suspend mode, the mode switching signal CL outputted in the low potential state is applied to the transistor Q31 of the power controller 30 so that the transistor Q31 is switched to the turn-off state. Due to the turn-off state of the transistor Q31, the output voltage Vo1 of the first power output unit 20 is applied to the transistor Q32 through the resistor R31, and the transistor Q32 is turned on. Switching.

Therefore, in the turn-on switching operation of the transistor Q32, the constant power of the first power output unit 20A is applied to the base terminal of the transistor Q33 through the resistor R32 and the zener diode ZD31. Accordingly, the transistor Q33 is switched to the turn-on state, and the transistor Q34 is switched to the turn-on state by the turn-on state of the transistor Q33. Therefore, the output voltage Vo1 of the first power output unit 20A is applied to the regulator REG.

Here, since the resistor R32 connected to the collector terminal of the transistor Q32 is an extremely small value compared to the resistor 31, the amount of current flowing through the resistor R32 and the zener diode ZD31 of the power control unit 30 is large. As a result, the amount of current flowing through the port diode of the power supply detecting unit 40 is reduced.

Therefore, the output signal of the power supply control unit 30 is applied to the control unit 50 so that the switching frequency of the control signal decreases according to the output signal so that the current flowing through the primary coil of the transformer T becomes the secondary side of the transformer T. Since the coil is less inductive, the suspend mode can eventually be reliably performed.

As described above, the present invention not only obtains a constant output voltage even in the suspend mode, but because the transistor Q32 is turned off in the normal mode, power is consumed only in the resistor R1, so that the temperature of the monitor increases due to heat generation. This has the effect of preventing power consumption and minimizing power consumption.

Claims (1)

The power supply controller 30 applying the output voltages Vo1 and Vo2 of the first and second power source output units 20A and 20B to the load LD1 and the regulator REG, respectively, in response to the mode switching signal CL. And a power source detecting unit 40 for remotely transmitting the current flowing through the power source control unit 30 as an output signal, and a switching frequency varying according to the output signal of the power source detecting unit 40 and flowing to the primary side of the transformer T. In the power supply having a control unit 50 for controlling the current, the power control unit 30 is a transistor (Q31) for switching operation according to the mode switching signal (CL), the turn-on switching of the transistor (Q31) In operation, the resistor R31 biases the output voltage Vo1 of the first power output unit 20 to the transistor Q31, and the transistor Q32 switches to the turn-off state by the turn-on switching operation of the transistor Q31. ) And a resistance R through which current flows according to the switching state of the transistor Q32. 32 and the zener diode ZD31, the transistor Q33 switching according to the switching state of the transistor Q32, and the switching state of the transistor Q33 to switch the output of the first power output unit 20A. And a transistor (Q34) for applying a voltage (Vo1) to the regulator (REG).